Optimising Outcomes in Gastrointestinal Neuroendocrine Tumours · of the neuroendocrine system Most...
Transcript of Optimising Outcomes in Gastrointestinal Neuroendocrine Tumours · of the neuroendocrine system Most...
OPTIMISING OUTCOMES IN GASTROINTESTINAL NEUROENDOCRINE TUMOURS
Dr Mairéad McNamara
Senior lecturer, University of Manchester & Honorary Consultant
in Medical Oncology, The Christie NHS Foundation Trust
The future
Targeted molecular therapy Research
Multidisciplinary approach
Investigations Treatment
What are neuroendocrine tumours?
Classification Symptoms
NEUROENDOCRINE TUMOURS:
OPTIMISING OUTCOMES
THE NEUROENDOCRINE SYSTEM
Neuro = nerve
Endocrine = network of glands
and organs in the body that
produce hormones
Neuroendocrine cells found in
endocrine glands – adrenal
glands, pancreas, thyroid,
pituitary and in ovaries and
testes
Source: http://cnx.org/content/col11496/1.6/; licensed under
the Creative Commons Attribution 3.0 Unported license
Source: http://www.ipsen.co.uk/ipsen_net.php;
reproduced with permission from Ipsen
Neuroendocrine tumour (NET) = tumour
of the neuroendocrine system
Most common locations are in the lungs
and digestive system
“Carcinoid” – when tumours arise in the
tubular gastrointestinal (GI) tract
Pancreatic neuroendocrine tumours
(pNETs) when they arise in the
pancreas
Gastrinomas when they arise in the
proximal portion of the duodenum
The more accurate description is NET
or gastroenteropancreatic (GEP) NET
(two categories – tumours of luminal GI
tract and pNETs)
NEUROENDOCRINE TUMOURS
https://images.google.com
Mid-1800s – first identified
1907 – “Carcinoid” – a tumour that
grew much more slowly than usual
cancers
1950s – could spread from one part of
the body to another like other forms of
cancer
1952 – carcinoid heart disease
identified1
1953 – flushing effect of serotonin
became clinically recognised1
NEUROENDOCRINE TUMOURS:
HISTORY
1. Modlin IM, et al., Human Pathology 2004; 35:1440-51.
2005
NET incidence by primary site
NEUROENDOCRINE TUMOURS:
INCIDENCE
Rare, incidence rising1 possibly due to
increased detection of asymptomatic
disease
As diagnostic imaging increases in
sensitivity, very small insignificant
NETs may be coincidentally
discovered
Most are sporadic (causes unknown)
but patients with multiple endocrine
neoplasia (MEN), neurofibromatosis
type 1 and von Hippel Lindau (VHL)
are at increased risk
1. Yao JC, et al., J Clin Oncol. 2008; 26:3063-72. Reprinted with permission. © 2008, American Society of Clinical Oncology. All rights reserved.
https://images.google.com
NEUROENDOCRINE TUMOURS:
CLASSIFICATION
NETs often grow slowly and it may take
years before symptoms appear and tumour
is diagnosed; well-differentiated
Some NETs may be fast-growing;
poorly-differentiated
ENETS / WHO 2010
Nomenclature and classification for digestive system NET
Tumour
differentiationGrade
Mitotic count
(in 10 high-power
fields)
Ki-67 index
(%)ENETS / WHO classification
Well-
differentiated
1 Low < 2 < 3Neuroendocrine tumour,
Grade 1
2 Intermediate 2-20 3-20Neuroendocrine tumour,
Grade 2
Poorly-
differentiated3 High >20 >20
Neuroendocrine carcinoma,
Grade 3 (small cell)
Neuroendocrine carcinoma,
Grade 3 (large cell)
https://images.google.com
NEUROENDOCRINE TUMOURS:
NON-FUNCTIONING
Non-functioning NETs:
Discovered incidentally during
surgery or on an investigation
being carried out for other
reasons
Do not overproduce hormones
May not cause symptoms
NEUROENDOCRINE TUMOURS:
SYMPTOMS
Symptoms:
Pain
Nausea
Change in bowel habits
Lung – chest infections, shortness
of breath, cough, haemoptysis
Overproduction of hormones
(functioning NETs):
Insulinomas – low blood glucose
Glucagonomas – high blood
glucose
VIPomas – diarrhoea
Gastrinomas – ulcers
Image made available under Creative Commons CC0 1.0 Universal Public Domain Dedication.
Some NETs (more commonly NETs of small bowel, large bowel or appendix) may
overproduce serotonin
Serotonin causes a characteristic collection of symptoms called the carcinoid
syndrome
NEUROENDOCRINE TUMOURS:
CARCINOID SYNDROME
Investigation Example
Blood tests Routine blood tests -
5-HIAA (serum or urine), chromogranin A, gut hormones, NT proBNP,
neuron-specific enolase
Imaging - Computerised Tomography (CT) scan
- Magnetic Resonance Imaging (MRI)
- Functional imaging - Somatostatin receptor scintigraphy (111-In
pentetreotide [Octreoscan] or Gallium Positron Emission
Tomography (PET) scan)
- Echocardiogram
Biopsy Establish differentiation
Endoscopy Diagnosis, excision
Further tests Bronchoscopy for lung NETs
NEUROENDOCRINE TUMOURS:
INVESTIGATIONS
Pancreatic gastrinoma stained for the
somatostatin receptor 2A; the cell membrane
is stained brown (400x magnification)
SOMATOSTATIN RECEPTORS
Somatostatin receptors 2 and 5
(SSTR2 and SSTR5) are expressed in
70-90% of NETs1
Result on somatostatin-receptor
scintigraphy is one factor that predicts
effectiveness of somatostatin
analogue therapy
Outcome according to SSTR
expression not known
1. Papotti M, et al. Expression of somatostatin receptor types 1–5 in 81 cases of gastrointestinal and pancreatic endocrine tumours.
Virchows Arch 2002;440:461–75. Copyright © 2002, Springer-Verlag. With permission of Springer.
68 GALLIUM DOTANOC PET
CT SCAN
Segment 1, 2, 3 and 4 of liver largely
replaced and expanded by tumour
Infiltration of adjacent segments 5 and
8 with multiple smaller discrete tracer
avid lesions in remaining segments
Multiple skeletal lesions
demonstrating intense tracer uptake;
T2 vertebra, right humeral head, left
anterior second rib, sternum, sacrum,
large destructive lesion left scapula
Courtesy of The Christie NHS Foundation Trust
REFERRAL TO SPECIALIST
CENTRE
Because of the rarity of these tumours, not all doctors and local hospitals will have
the full expertise to deal with this type of diagnosis
Referral to a NET centre of excellence may be required
PATIENT
Radiologist
Pathologist
Surgeon
Oncologist
Nurse specialists
Gastroenterologist
Endocrinologist
Co-ordinator
General Practitioner
NEUROENDOCRINE TUMOURS:
MULTIDISCIPLINARY MEETING
Depends on:
Primary site of NET
Classification
Size of the tumour and whether it has metastasised
Whether patient has carcinoid syndrome or overproduction of
other hormones
A watch and wait approach may be adopted in selected cases of
incidental NETs
NEUROENDOCRINE TUMOURS:
TREATMENT
Management by site:
Gastric
Management depends on type
(whether 1, 2 or 3)
Pancreas
Resection indicated to alleviate
symptoms due to hormone
overproduction, local mass
effect, prevent malignant
transformation or dissemination
Ampulla of Vater
Resection
Small bowel NET
Resection
LOCALISED GASTROINTESTINAL
NEUROENDOCRINE TUMOURS:
TREATMENT1
Appendix
<2 cm - simple appendicectomy
(no mesoappendix invasion)
>2 cm or mesoappendiceal
invasion – right hemicolectomy
Rectal NET
<1 cm and T1 – local
endoscopic resection
1-2 cm – controversial –
individualised treatment
required
>2 cm – resection
1. Please refer to European Neuroendocrine Tumour Society (ENETS) guidelines 2016.
Follow-up:
May include:
Biochemical markers (5-HIAA (serum or urine), chromogranin
A, gut hormones, neuron-specific enolase)
Imaging (as appropriate)
Functional imaging (Somatostatin receptor scintigraphy (111-
In pentetreotide [Octreoscan] or Gallium Positron Emission
Tomography (PET) scan) should be performed where
recurrence is suspected
RESECTED GASTROINTESTINAL
NEUROENDOCRINE TUMOURS:
FOLLOW-UP1
1. Please refer to ENETS guidelines 2016.
There is no high level evidence to support the role of functional
imaging (somatostatin receptor scintigraphy [111-In pentetreotide
(Octreoscan)] or gallium positron emission tomography [PET] scan)
in response evaluation of patients with advanced gastrointestinal
NETs
ADVANCED GASTROINTESTINAL
NETs: FOLLOW-UP1
1. Please refer to ENETS guidelines 2016.
Treatment goals: (care tailored to suit individual patient)
Remove the tumour by surgery, however, if the tumour has metastasised, this
may not be possible
Alleviate symptoms
Control tumour growth
Maintain patient quality of life
NEUROENDOCRINE TUMOURS:
TREATMENT
Courtesy of The Christie NHS Foundation Trust
Hormone Hyper-secretion
Somatostatin analogues
Agents appropriate to specific syndrome
Resectable hepatic metastases Consider surgery
Asymptomatic
Observation alone
Somatostatin analogues at disease
progression or if symptomatic
ADVANCED GASTROINTESTINAL
NETS: INITIAL THERAPY
PROMID1
CLARINET2
SOMATOSTATIN ANALOGUES
1. Rinke A, et al. J Clin Oncol 2009;27:4656–63; 2. Caplin ME, et al. N Engl J Med 2014; 371:224–33.
Log-rank test p < 0.001,
HR = 0.34 (95% CI 0.20-0.59)
RDouble blind
Placebo (n=43)
IM every 28 days
Octreotide LAR (n=42)
30 mg IM every 28 days
Octreotide LAR significantly lengthens
time to tumour progression compared
with placebo in patients with
functionally active and inactive
metastatic midgut NETs
Patients with:
Treatment-naïve
Well differentiated
(95% Ki-67 ≤2%)
Metastatic mid-gut NETs
Primary endpoint:
Time to tumour progression
PROMID:
OCTREOTIDE LAR - PHASE 3
Rinke A, et al., J Clin Oncol. 2009;27:4656-63 Reprinted with permission. © 2009, American Society of Clinical Oncology. All rights reserved.
.
Tumours originated in pancreas,
mid-gut, hindgut or of unknown
origin
96% no tumour progression in 3-6
months before randomisation
84% patients had no previous
treatment
Well differentiated (Ki-67<10%)
Primary endpoint:
Progression-free survival (PFS)
CLARINET:
LANREOTIDE - PHASE 3
Lanreotide is associated with
significantly prolonged PFS among
patients with metastatic
enteropancreatic NETs (Grade 1 or 2)
RDouble blind
Placebo (n=103)
SC every 28 days
Lanreotide (n=101)
120 mg SC every 28 days
From N Engl J Med. 2014, Caplin ME, et al., Lanreotide in Metastatic Enteropancreatic Neuroendocrine Tumors, 371: 224–33. Copyright © 2014,
Massachusetts Medical Society. Reprinted with permission from Massachusetts Medical Society.
PFS: According to sub-groups
CLARINET:
LANREOTIDE – PHASE 3
RDouble blind
Placebo (n=103)
SC every 28 days
Lanreotide (n=101)
120 mg SC every 28 days
From N Engl J Med. 2014, Caplin ME, et al. Lanreotide in Metastatic Enteropancreatic Neuroendocrine Tumors, 371:224–33.
Copyright © 2014, Massachusetts Medical Society. Reprinted with permission from Massachusetts Medical Society.
Median progression-free survival data2
Lanreotide: not reached
Placebo: 12.1 months
(95% CI 9.4-18.3 months)
HR for progressive disease/death 0.58, 95% CI
0.32-1.04
CLARINET1:
LANREOTIDE - PHASE 3 (pNET)
RDouble blind
Placebo (n=49)
SC every 28 days
Lanreotide (n=42)
120 mg SC every 28 days
PFS: According to pNET2 sub-group
Mean age – 64 years both groups
Overall: 37% had hepatic tumour
load >25%, 95% stable disease, 77%
had received no previous treatment,
38% had previous surgery on the
tumour
No new safety concerns
The positive risk-benefit profile for
lanreotide depot in pNETs is
consistent with overall findings in
CLARINET
1. Caplin ME, et al., N Engl J Med. 2014; 371:224-33.
2. Phan AT, et al., J Clin Oncol. 2015; 33 (suppl 3; abstr 233).
Progressive disease
Symptomatic
Somatostatin analogues
Everolimus
Symptomatic from tumour bulkSomatostatin analogues
+/- targeted therapy
Highly symptomatic Chemotherapy1
Hepatic arterial embolisation
Sunitinib
Liver-predominant disease
PANCREATIC NETS:
PROGRESSIVE DISEASE
1. Fine RL, et al., J Clin Oncol . 2014;32 (suppl 3; abstr 179).
Mature median overall survival data2
Everolimus: 44.02 months
(95% CI 35.61-51.75)
Placebo: 37.68 months
(95% CI 29.14-45.77)
HR 0.94, 95% CI 0.73-1.20, P=0.30
Crossover of majority of patients (85%)
may have confounded results.
Everolimus significantly improved PFS as compared to placebo in patients with advanced pNETs
Everolimus: Oral inhibitor of mammalian target of
rapamycin (mTOR)
Patients with:
Advanced, low- or intermediate-grade pNET
40% therapy naïve
Radiologic progression within previous 12 months
Primary endpoint: Progression-free survival
EVEROLIMUS (RADIANT-3)1:
pNET PHASE 3
1. From Yao JC, et al., N Engl J Med. 2011; Everolimus for Advanced Pancreatic Neuroendocrine Tumors; 364:514–23. Copyright © 2011. Massachusetts
Medical Society. Reprinted with permission from Massachusetts Medical Society. 2. Yao JC, et al., ESMO 2014; abstract 11320.
RDouble blind
Placebo (n=203)
Everolimus (n=207)
10 mg/day continuously
OSPFS
2x PFS: 11.4 v 5.5 months
P<0.001
Sunitinib: Multi-targeted tyrosine kinase inhibitor
Patients with:
Well-differentiated advanced pNETs
Majority had received prior systemic therapy
Radiologic progression within previous 12 months
Primary endpoint: Progression-free survival
SUNITINIB: pNET PHASE 3
RDouble blind
Placebo (n=85)
Sunitinib (n=86)
37.5mg/day continuously
Sunitinib improved PFS and OS as compared to placebo in patients with advanced pNETs
From Raymond E, et al., N Engl J Med. 2011; Sunitinib Malate for the Treatment of Pancreatic Neuroendocrine Tumors.
364:501-13. Copyright © 2011. Massachusetts Medical Society. Reprinted with permission from Massachusetts Medical Society.
Symptomatic from tumour bulkSomatostatin analogues
+/- Chemotherapy
Liver-predominant disease Hepatic arterial embolisation
Refractory to medical therapyPeptide receptor radioligand therapy
(PRRT) – where available
SMALL BOWEL NETS:
PROGRESSIVE DISEASE
Use of targeted radiotherapy using radiolabeled somatostatin analogues, in the
treatment of patients with NETs
Data previously generated in populations of patients with combined pancreatic and
gastrointestinal NETs
In general, objective tumour response rates were up to 30%
Approximately one-third of patients had symptomatic improvement1
PEPTIDE RECEPTOR
RADIONUCLIDE THERAPY: PRRT
1. Kwekkeboom DJ, et al., J Clin Oncol. 2008; 26(13):2124-30.
Evaluate the efficacy and safety of 177Lu-Dotatate plus Octreotide 30 mg compared to
Octreotide LAR 60 mg (off-label use)2 in patients with inoperable, somatostatin receptor positive,
midgut NET, progressive on Octreotide LAR 30 mgAIM
International, multicentre, randomised, comparator-controlled, parallel-groupDESIGN
Treatment and AssessmentsTumour burden assessment (RECIST criteria) every 12 weeks
4 administrations of 7.4 GBq of 177Lu-Dotatate
every 8 weeks + Octreotide 30 mgn = 115
n = 115 Octreotide LAR 60mg every 4 weeks
5 Years
follow up
BASELINE
AND
RANDOMISATION
NETTER-11:
STUDY OBJECTIVES AND DESIGN
1. Strosberg J, et al., ECC Vienna 2015. Abstract 6LBA.
2. FDA and EMA recommendation.
N = 229 (ITT)
Number of events: 90
• 177Lu-Dotatate: 23
• Oct 60 mg LAR: 67
HR [95% CI]
0.209 [0.129 – 0.338]
p < 0.0001
177Lu-Dotatate
Median PFS: Not reached
Octreotide LAR 60 mg
Median PFS: 8.4 months
Significant increase in PFS in patients with advanced midgut NETs
treated with 177Lu-Dotatate
NETTER-1:
PROGRESSION-FREE SURVIVAL
Strosberg J, et al. Presented at the ECC, Vienna, September 2015; abstract 6LBA. Reprinted with permission from Johnathan Strosberg.
Everolimus 10 mg/day
N=205Treated until PD,
intolerable AE, or
consent withdrawal.
Patients with well-differentiated
(G1/G2), advanced, progressive,
nonfunctional NET of lung or GI
origin (N=302).
• Absence of active or any history of
carcinoid syndrome.
• Pathologically-confirmed advanced
disease.
• Radiologic disease progression in ≤ 6
months.
2:1
R
A
N
D
O
M
I
S
E
Placebo
N=97
Endpoints:
• Primary: PFS (central)
• Key Secondary: OS
• Secondary: ORR, DCR, safety, HRQoL (FACT-G), WHO PS, NSE/CgA, PK
Stratified by:
• Prior SSA treatment (yes vs. no)
• Tumour origin (stratum A vs. B)*
• WHO PS (0 vs. 1)
*Based on prognostic level, grouped as: Stratum A (better prognosis) appendix, caecum, jejunum, ileum, duodenum, and NET of unknown
primary. Stratum B (worst prognosis) lung, stomach, rectum, and colon except caecum.
Crossover to open-label everolimus after progression in the placebo arm was not allowed prior to the primary analysis.
RADIANT-4:
STUDY DESIGN
Yao JC, et al., Lancet, 2016; 387:968-77.
52% reduction in the relative risk of progression or death with everolimus vs placebo
HR = 0.48 (95% CI, 0.35-0.67); P < 0.00001
205 168 145 124 101 81 65 52 26 10 3 0 0
97 65 39 30 24 21 17 15 11 6 5 1 0Placebo
Everolimus
No.of patients still at risk
0 2 4 6 8 10 12 15 18 21 24 27 30
Months
0
10
20
30
40
50
60
70
80
90
100
Pro
ba
bilit
y o
f P
rog
res
sio
n-f
ree
Su
rviv
al
(%)
Kaplan–Meier medians
Everolimus: 11.0 months (95% CI, 9.23-13.31)
Placebo: 3.9 months (95% CI, 3.58-7.43)
Censoring Times
Everolimus (n/N = 113/205)
Placebo (n/N = 65/97)
P-value is obtained from the stratified one-sided log-rank test; Hazard ratio is obtained from stratified Cox model.
RADIANT-4:
PROGRESSION-FREE SURVIVAL
Reprinted from Yao JC, et al. Lancet 2016;387:968–77. Everolimus for the treatment of advanced, non-functional neuroendocrine tumours of the lung or
gastrointestinal tract (RADIANT4): a randomised, placebo controlled, phase 3 study. Copyright 2016, with permission from Elsevier.
Telotristat etiprate is a novel
inhibitor of tryptophan
hydroxylase, the rate-limiting
enzyme in serotonin biosynthesis
TELESTAR1: TELOTRISTAT
ETIPRATE (MECHANISM OF ACTION)
1. Kulke MH, et al., ECC Vienna 2015. Abstract 37LBA.
2. Druce M, et al. Nature Reviews Endocrinology 2009;5:276-283. Reprinted by permission from Macmillan Publishers Ltd:
Nature Reviews Endocrinology Fibrosis and carcinoid syndrome: from causation to future therapy. Copyright 2009.
2
Telotristat etiprate 500 mg TID* (n=45)
Telotristat etiprate 250 mg TID (n=45)
Placebo TID (n=45)
All patients required to be on SSA at enrollment and continue SSA therapy throughout study period
1:1:1
3- to 4-week
run-in (n=135)R
Telotristat
etiprate
500 mg TID
Evaluation of primary endpoint:
Reduction in number of daily BMs from baseline (averaged over 12-
week double-blind treatment phase)
Run in: Evaluation of
bowel movement (BM)
frequency
(well differentiated
metastatic NET with
documented carcinoid
syndrome with ≥4
BMs/day).
TELESTAR:
STUDY DESIGN
Kulke MH, et al., ECC Vienna 2015. Abstract 37LBA.
*Including a blinded titration step of one week of 250 mg TID.
BM; bowel movement, SSA; somatostatin analogue, TID; three times daily.
ClinicalTrials.gov. NCT01677910 TELESTAR. Available at: https://clinicaltrials.gov/ct2/show/NCT01677910. Accessed September 2015.
Hodges–Lehmann estimator of treatment differences showed a median reduction versus placebo of
–0.81 BMs daily for telotristat etiprate 250 mg dose (P<0.001)
–0.69 for telotristat etiprate 500 mg dose (P<0.001)
TELESTAR: STUDY DESIGN
Kulke MH, et al., ECC Vienna 2015. Abstract 37LBA. Reprinted with permission from Matthew Kulke.
Systemic chemotherapy with a platinum-based combination regimen, analogous to
that used for small cell lung cancer
Anti-tumoural activity and high tumour response rates (41-67%)1
No established second-line treatment
All studies to date are small retrospective series:
FOLFIRI2 (N=19)
FOLFOX3 (N=21)
Temozolomide-based regimens4 (N=25)
Topotecan5 (N=22)
Taxotere-based chemotherapy6 (N=20)
POORLY-DIFFERENTIATED NE
CARCINOMAS (ADVANCED):
ROLE OF CHEMOTHERAPY
1. Moertel CG, et al., Cancer. 1991;68:227-32; 2. Hentic O, et al., Endocr Relat Cancer. 2012;19:751-7; 3. Hadoux J, et al., ENETS, 2013;
4. Welin S, et al., Cancer. 2011;117:4617-22; 5. Olsen PS, et al., J of Cancer. 2014;5:628-32; 6. Sorbye H, et al., Ann Oncol. 2013;24(1):152-60.
Some ongoing studies1:
Maintenance therapy
Lanreotide as maintenance therapy in patients with non-resectable
duodeno-pancreatic NETs (REMINET – NCT 02288377)
Sequencing of therapy
Everolimus followed by Streptozotocin/5-fluorouracil upon progression or
reverse sequence in pancreatic NET (SEQTOR – NCT 02246127)
Combination therapy with PRRT and chemotherapy
Capecitabine/Temozolomide +/- PRRT in patients with well-differentiated
midgut NETs (NCT 02358356)
THE FUTURE
1. ClinicalTrials.gov
THANK YOU